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Fisika IntiNuclear Physics
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Pengertian Modern: Gambar “onion” Modern understanding: the ``onion’’ picture
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Let’s see what’s inside!
Atom
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Let’s see what’s inside!
Nucleus
Pengertian Modern: Gambar “onion” Modern understanding: the ``onion’’ picture
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Let’s see what’s inside!
Protons and
neutrons
Next chapter…
Pengertian Modern: Gambar “onion” Modern understanding: the ``onion’’ picture
Pendahuluan: Perkembangan Fisika Inti Introduction: Development of Nuclear Physics 1896 – the birth of nuclear physics
Becquerel discovered radioactivity in uranium compounds
Rutherford showed the radiation had three types Alpha (He nucleus) Beta (electrons) Gamma (high-energy photons)
1911 Rutherford, Geiger and Marsden performed scattering experiments Established the point mass nature of the nucleus Nuclear force was a new type of force
1919 Rutherford and coworkers first observed nuclear reactions in which naturally occurring alpha particles bombarded nitrogen nuclei to produce oxygen
1932 Cockcroft and Walton first used artificially accelerated protons to produce nuclear reactions
1932 Chadwick discovered the neutron
1933 the Curies discovered artificial radioactivity
1938 Hahn and Strassman discovered nuclear fission
1942 Fermi achieved the first controlled nuclear fission reactor
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29.1 Some Properties of Nuclei
All nuclei are composed of protons and neutrons Exception is ordinary hydrogen with just a proton
The atomic number, Z, equals the number of protons in the nucleus The neutron number, N, is the number of neutrons in the nucleus The mass number, A, is the number of nucleons in the nucleus
A = Z + N Nucleon is a generic term used to refer to either a proton or a neutron The mass number is not the same as the mass
Notation
Example:
Mass number is 27 Atomic number is 13 Contains 13 protons Contains 14 (27 – 13) neutrons
The Z may be omitted since the element can be used to determine Z
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XA
Zwhere X is the chemical symbol of the element
Al27
13
Muatan dan massa Charge and mass
Charge: The electron has a single negative charge, -e (e = 1.60217733 x 10-19 C)
The proton has a single positive charge, +e Thus, charge of a nucleus is equal to Ze
The neutron has no charge Makes it difficult to detect
Mass: It is convenient to use atomic mass units, u, to express masses
1 u = 1.660559 x 10-27 kg
Based on definition that the mass of one atom of C-12 is exactly 12 u
Mass can also be expressed in MeV/c2
From ER = m c2
1 u = 931.494 MeV/c2
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Ringkasan Massa Summary of Masses
Masses
Particle kg u MeV/c2
Proton 1.6726 x 10-27 1.007276 938.28
Neutron 1.6750 x 10-27 1.008665 939.57
Electron 9.101 x 10-31 5.486x10-4 0.511
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Quick problem: protons in your body
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What is the order of magnitude of the number of protons in your body? Of the number of neutrons? Of the number of electrons? Take your mass approximately equal to 70 kg.
An iron nucleus (in hemoglobin) has a few more neutrons than protons, but in a typical water molecule there are eight neutrons and ten protons. So protons and neutrons are nearly equally numerous in your body, each contributing 35 kg out of a total body mass of 70 kg.
Same amount of neutrons and electrons.
28
27
1nucleon35 10 protons
1.67 10N kg
kg
Ukuran Inti The Size of the Nucleus
First investigated by Rutherford in scattering experiments
He found an expression for how close an alpha particle moving toward the nucleus can come before being turned around by the Coulomb force
The KE of the particle must be completely converted to PE
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2
2
4 ek Zed
mv
2 1 221
2e e
e Zeq qmv k k
r dor
For gold: d = 3.2 x 10-14 m, for silver: d = 2 x 10-14 m
Such small lengths are often expressed in femtometers where 1 fm = 10-15 m (also called a fermi)
Ukuran Inti Size of Nucleus
Since the time of Rutherford, many other experiments have concluded the following
Most nuclei are approximately spherical
Average radius is
ro = 1.2 x 10-15 m
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31
oArr
Kerapatan Inti Density of Nuclei
The volume of the nucleus (assumed to be spherical) is directly proportional to the total number of nucleons
This suggests that all nuclei have nearly the same density
Nucleons combine to form a nucleus as though they were tightly packed spheres
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Kesetabilan Inti Nuclear Stability
There are very large repulsive electrostatic forces between protons These forces should cause the nucleus to fly apart
The nuclei are stable because of the presence of another, short-range force, called the nuclear (or strong) force This is an attractive force that acts between all nuclear particles
The nuclear attractive force is stronger than the Coulomb repulsive force at the short ranges within the nucleus
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Grafik Kesetabilan Inti Nuclear Stability chart
Light nuclei are most stable if N = Z
Heavy nuclei are most stable when N > Z As the number of protons increase, the
Coulomb force increases and so more nucleons are needed to keep the nucleus stable
No nuclei are stable when Z > 83
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Isotop Isotopes
The nuclei of all atoms of a particular element must contain the same number of protons
They may contain varying numbers of neutrons
Isotopes of an element have the same Z but differing N and A values
Example:
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C11
6C14
6C13
6C12
6
29.2 Binding Energy
The total energy of the bound system (the nucleus) is less than the combined energy of the separated nucleons This difference in energy
is called the binding energyof the nucleus It can be thought of as the
amount of energy you need to add to the nucleus to break it apart into separated protons and neutrons
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Binding Energy per Nucleon
Binding Energy Notes
Except for light nuclei, the binding energy is about 8 MeV per nucleon
The curve peaks in the vicinity of A = 60 Nuclei with mass numbers greater than or less than 60 are not as
strongly bound as those near the middle of the periodic table
The curve is slowly varying at A > 40 This suggests that the nuclear force saturates
A particular nucleon can interact with only a limited number of other nucleons
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29.3 Radioaktiv Radioactivity
Radioactivity is the spontaneous emission of radiation
Experiments suggested that radioactivity was the result of the decay, or disintegration, of unstable nuclei
Three types of radiation can be emitted Alpha particles
The particles are 4He nuclei
Beta particles The particles are either electrons or positrons
A positron is the antiparticle of the electron It is similar to the electron except its charge is +e
Gamma rays The “rays” are high energy photons
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Distinguishing Types of Radiation
The gamma particles carry no charge
The alpha particles are deflected upward
The beta particles are deflected downward A positron would be deflected
upward
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Penetrating Ability of Particles
Alpha particles
Barely penetrate a piece of paper
Beta particles
Can penetrate a few mm of aluminum
Gamma rays
Can penetrate several cm of lead
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Sheet of paper
Few mm of aluminium
Few cm of lead
particles cannot pass through paper
particles cannot pass through aluminium
particles cannot pass through lead
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Dangers of radioactivity – OUTSIDE BODY
OUTSIDE the body and are more dangerous as they can penetrate the skin into your body to your organs.
Alpha
Radiation will ionise atoms in living cells – this can damage them and cause cancer or leukaemia.
GammaGamma
Beta
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INSIDE the body an radiation is the most dangerous because it has not enough energy to pass out of the body and has the greatest ionization power to damage cells.
β and are less dangerous because they have enough energy to pass out of the body
Gamma
Beta
Alpha
Dangers of radioactivity – INSIDE BODY
Kurva Decay Curve
The decay curve follows the equation
The half-life is also a useful parameter
The half-life is defined as the time it takes for half of any given number of radioactive nuclei to decay
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693.02lnT 21
0
tN N e
What fraction of a radioactive sample has decayed after twohalf-lives have elapsed?
(a) 1/4(b) 1/2(c) 3/4 (d) not enough information to say
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QUICK QUIZ
(c). At the end of the first half-life interval, half of the original sample
has decayed and half remains. During the second half-life interval, half
of the remaining portion of the sample decays. The total fraction of the
sample that has decayed during the two half-lives is: 1 1 1 3
2 2 2 4
Karakteristik Sinar-X Characteristic X-Rays
When a metal target is bombarded by high-energy electrons, x-rays are emitted
The x-ray spectrum typically consists of a broad continuous spectrum and a series of sharp lines
The lines are dependent on the metal
The lines are called characteristic x-rays
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Penjelasan Karakteristik Sinar-X Explanation of Characteristic X-Rays The details of atomic structure can be used to
explain characteristic x-rays
A bombarding electron collides with an electron in the target metal that is in an inner shell
If there is sufficient energy, the electron is removed from the target atom
The vacancy created by the lost electron is filled by an electron falling to the vacancy from a higher energy level
The transition is accompanied by the emission of a photon whose energy is equal to the difference between the two levels
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Penggunaan Radioaktiv Uses of Radioactivity
Carbon Dating Beta decay of 14C is used to date organic samples
The ratio of 14C to 12C is used
Smoke detectors Ionization type smoke detectors use a radioactive source to ionize the air
in a chamber
A voltage and current are maintained
When smoke enters the chamber, the current is decreased and the alarm sounds
Radon pollution Radon is an inert, gaseous element associated with the decay of radium
It is present in uranium mines and in certain types of rocks, bricks, etc that may be used in home building
May also come from the ground itself
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29.5 Natural Radioactivity
Classification of nuclei Unstable nuclei found in nature
Give rise to natural radioactivity
Nuclei produced in the laboratory through nuclear reactions Exhibit artificial radioactivity
Three series of natural radioactivity exist Uranium
Actinium
Thorium
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Decay Seriesof 232Th
Series starts with 232Th
Processes through a series of alpha and beta decays
Ends with a stable isotope of lead, 208Pb
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29.6 Nuclear Reactions
Structure of nuclei can be changed by bombarding them with energetic particles
The changes are called nuclear reactions
As with nuclear decays, the atomic numbers and mass numbers must balance on both sides of the equation
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Which of the following are possible reactions?
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Problem
(a) and (b). Reactions (a) and (b) both conserve total charge and total
mass number as required. Reaction (c) violates conservation of mass
number with the sum of the mass numbers being 240 before reaction
and being only 223 after reaction.
Q Values
Energy must also be conserved in nuclear reactions The energy required to balance a nuclear reaction is
called the Q value of the reaction
An exothermic reaction There is a mass “loss” in the reaction There is a release of energy Q is positive
An endothermic reaction There is a “gain” of mass in the reaction Energy is needed, in the form of kinetic energy of the incoming
particles Q is negative
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Threshold Energy
To conserve both momentum and energy, incoming particles must have a minimum amount of kinetic energy, called the threshold energy
m is the mass of the incoming particle
M is the mass of the target particle
If the energy is less than this amount, the reaction cannot occur
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QM
m1KEmin
If the Q value of an endothermic reaction is -2.17 MeV, the minimum kinetic energy needed in the reactant nuclei if the reaction is to occur must be (a) equal to 2.17 MeV, (b) greater than 2.17 MeV, (c) less than 2.17 MeV, or (d) precisely half of 2.17 MeV.
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QUICK QUIZ
(b). In an endothermic reaction, the threshold energy exceeds the
magnitude of the Q value by a factor of (1+ m/M), where m is the
mass of the incident particle and M is the mass of the target nucleus.